CPU


SiFive Unveils Freedom Platforms for RISC-V-Based Semi-Custom Chips

SiFive Unveils Freedom Platforms for RISC-V-Based Semi-Custom Chips

SiFive, a company established by researchers who invented the RISC-V instruction set architecture in the University of California Berkeley several years ago, has this week announced two platforms which could be used to design semi-custom SoCs based on RISC-V cores. SiFive is the world’s first and yet the only company developing chips featuring the RISC-V ISA and it already has initial customers interested in designing SoCs for machine learning, storage, embedded, IoT and wearable applications.

SiFive: World’s First Developer of Commercial RISC-V Chips

RISC-V is an open-source microprocessor architecture developed by researchers in the Computer Science Division at UC Berkeley and officially introduced in 2010. It has since been evolved by various both academic researchers and volunteers. The CPU ISA was designed for various applications including mobile and embedded devices, and is available free under a BSD license. Those who adopt RISC-V can develop either open and free cores, or closed and proprietary cores, which is good for developing commercial projects that do not want to share secrets with rivals.

A number of companies (including huge ones like Google, Hewlett Packard Enterprise and Oracle) recently joined the RISC-V Foundation, but barely any organization has unveiled an actual RISC-V-based commercial chip (what they have internally is anyone’s guess). Basically, as far as we know, the technology has never left various research labs. As a result the original team that worked on the technology at UC Berkeley founded SiFive, which is going to develop commercial semi-custom SoCs for various applications featuring RISC-V cores as well as third-party IP.

New Semi-Custom Chip Business Model

Chips are used for a lot of applications and in the coming years the need for custom SoCs will only grow as customers demand specialized hardware for their problem sets. However, development of modern SoCs is not a very affordable task from a financial standpoint. To build a simple chip, one needs to license the general-purpose compute cores (or ISA itself) from companies like ARM or Imagination Technologies, but to also get a variety of supporting IP (e.g., memory controllers, I/O interfaces, etc.) either from developers like Rambus, or build everything from scratch. Licensing typically requires companies to pay an upfront fee for a set of rights, and an SDK, and then royalties for every ASIC (application specific integrated circuit) containing the IP that they sell. In other words, a company building a chip needs to make a hefty investment to begin, and then the licensing fees will affect the pricing of every unit sold. Moreover, to create a chip, one needs a semiconductor development team to specify requirements, design the IC (integrated circuit), tape it out, analyze defects and implement fixes (if needed). Hiring a dedicated development team for just one chip is expensive and complicated. As a result, many newcomers need either to join bigger players (who have appropriate teams inhouse), or concentrate on software and utilize off-the-shelf silicon to build modern devices. SiFive plans to design semi-custom chips for the latter companies using RISC-V cores as well as its common Freedom platforms and technologies. Use of RISC-V cores (as well as common components designed by SiFive) is being touted to help to significantly lower development costs.

The company promises that its approach will enable players without significant financial and technological backing to get their own custom SoCs with their own special-purpose IP. SiFive claims that it will be able not only to integrate third-party IP into chips, but also add custom features, such as RISC-V extensions, accelerators, or co-processors. Moreover, the chip designer can also help its partners to integrate their unique intellectual property. In fact, SiFive can manage the entire process of chip development and manufacturing and then supply its clients the final manufactured chip for commercial applications.

From many points of view, SiFive’s business model resembles that of AMD’s EESC (enterprise, embedded and semi-custom) division, which develops SoCs for companies like Microsoft and Sony. The important difference between SiFive and other developers of semi-custom chips is that SiFive publishes all the low-level specs of its Freedom Unleashed and Freedom Everywhere platforms necessary for software development (e.g., memory maps, debug interfaces, interrupt control, etc.), whereas RISC-V Foundation provides basic development tools to make it considerably easier for programmers to design software for chips based on the microarchitecture. In fact, the software side of the story here is no less important than the hardware part. The use of the BSD license for a lot of this further lowers the investments required to deliver a solution involving a custom silicon and supporting software. For example, SiFive tells us that there is a lot of standard software (e.g., FreeBSE, FreeRTOS, etc) that already works on the Freedom platforms (on RISC-V-based platforms, to be more precise), so its customers only need to focus on their particular area of chip and software differentiation. However, it has been noted that customer specific extensions to the RISC-V ISA could certainly break some level of software compatibility, depending what is used and how.

“This expands on the tremendous amount of momentum in the RISC-V ecosystem,” said Jack Kang, VP of product and business development at SiFive. “Besides the ports and software targeted for the RISC-V ISA, these platforms will enable OS and other low-level software to be targeted to a standard platform specification.”

Two Platforms

Initially, SiFive will offer its clients two base platforms for different applications: the Freedom Unleashed (U500) for performance-demanding applications as well as the Freedom Everywhere (E300) for low-power devices. Both platforms have been verified with TSMC and can allow SiFive to quickly add customizations, which is what their customers require and which greatly speeds up time-to-market, simply because the bigger parts of Freedom-based ASICs have already been developed.

The SiFive Freedom U500 platform will feature up to eight 64-bit cache-coherent Unix-capable RISC-V cores. Each SoC based on the U500 features four DDR3/DDR4 DRAM channels with ECC support, PCIe 3.0, USB 3.0 (with OTG support), Gigabit Ethernet, power management, a variety of peripheral interfaces (e.g., SD/eMMC, GPIO, UART, I2C, etc.) and so on. SiFive can add various extensions to the general-purpose cores to meet demands of clients, add custom input/output interfaces, custom co-processors/accelerators and other IP. The chip designer verified its Freedom U500 platform with TSMC’s 28nm process technology and thus can quickly incorporate additional blocks, tape out the product and manufacture it using a proven process technology. SiFive tells us that several companies designing solutions for machine learning, storage, and networking have already expressed interest in using the U500 platform directly with SiFive.

The SiFive Freedom E300 platform is intended for less demanding applications, which is why it is powered by a 32-bit single-issue in-order general purpose RISC-V core, which can be customized or enhanced to meet specific needs. The design supports on-chip memory and can support various interface technologies, including SD/eMMC, USB 1.1, GPIO, UART, I2C and so on. The Freedom E300 is optimized for TSMC’s 180 nm fabrication process, which is 15 years old and which is still used for many chips that are not complex and do not run at high frequencies. According to the chip developer, customers working on embedded microcontrollers, IoT, and wearables have demonstrated some interest in the E300 platform.

Default die sizes and cost have not been explicitly mentioned by SiFive at this time – it will be up to the customer IP and financial arrangements on a per-customer basis.

New Horizons

The management of SiFive stresses that the two platforms, which the company announced this month, are only the beginning for SiFive and more will be incoming. At a high level, this should broaden the number of markets that SiFive can address. Those future platforms will use different process technologies depending on requirements of appropriate applications. Keeping in mind the key promise of SiFive: low-cost development of custom SoCs. 

SiFive does not elaborate how much money its customers will be able to save due to the free RISC-V microarchitecture, any pre-developed platforms (with re-used components), proven silicon, open-source software or other advantages that the company has to offer. This is understandable because every customer product could be unique in complexity and customization. However, SiFive says that in certain cases it will be able to deliver products to startups that do not have any silicon teams at all, which essentially means that the developer plans to address needs of very small players. Typically, such companies cannot get access to custom silicon because of high costs and other difficulties, but SiFive implies that with their pre-developed Freedom platforms the startups may get their chance to build semi-custom chips and take advantage of things like higher performance and/or lower power consumption compared to off-the-shelf not-customized silicon or FPGAs. The VP of SiFive told us that he could see a future where a couple of engineers in a garage can get access to a custom SoC “with a moderate Kickstarter campaign.”

SiFive claims that it is a fabless semiconductor company which specializes in the development of various chips based on RISC-V-compatible cores. While semi-custom RISC-V SoCs may not be the most lucrative market segment, SiFive is the only player here and the company will clearly try to capitalize on its unique position. SiFive’s decision to use the RISC-V ISA is natural given the background of its founders, as well as the company’s business model (RISC-V is free). However, background and costs are not the only reason here. The interest towards the microarchitecture is growing – in recent months, companies like AMD, Google, IBM, NVIDIA, Microsoft, Qualcomm and Western Digital joined RISC-V Foundation, which manages the development of the technology.

Given the nature of semi-custom chip business, SiFive cannot disclose the names of companies interested in its platforms and since this is a private company, it does not need to confirm whether it is developing any commercial chips at all. However, given the interest for RISC-V from the aforementioned industry heavyweights, it looks like SiFive is a company to watch, not only because it could build interesting semi-custom SoCs, but because it could actually develop the industry’s first commercial chips based on open-source RISC-V microarchitecture.

Intel Quietly Speeds Up Skylake-U: i7-6660U now in Price List

Intel Quietly Speeds Up Skylake-U: i7-6660U now in Price List

Intel has quietly added a new Skylake-U processor into its price list. The new Intel Core i7-6660U system-on-chip is designed for low-power notebook systems and provides higher performance than its direct predecessor, the Core i7-6650U, and sits on the top of Intel’s 15W mobile CPU stack.

The new Intel Core i7-6660U belongs to the Skylake-U family of processors that feature CPU and PCH on the same piece of substrate and are used to build mobile PCs with low power consumption. The new chip is currently only listed in Intel’s price list, which reveals its general specs (two cores with hyperthreading, 4 MB L3 cache and 2.40 GHz clock-rate, no word on turbo) as well as its price of $415 in 1000-unit quantities. The CPU costs the same amount of money as the Core i7-6650U and the Core i7-6560U.

If the Core i7-6660U chip shares general design with its predecessor, then it features two cores with Hyper-Threading technology clocked at 2.40 GHz (up 200 MHz from the i7-6650U), 4 MB L3 cache, a dual-channel memory controller (support for DDR4-2133, LPDDR3-1866 and DDR3L-1600 memory), Intel Iris Graphics 540 (48 execution units with 64 MB eDRAM, up to 1.05 GHz clock rate, up to 806.4 GFLOPS compute performance) as well as a 15 W TDP. The new processor should also support all the technologies that other Skylake-generation mobile Core i7 chips support, including AES-NI, AVX 2, vPro, virtualization (VT-x, VT-d), software guard extensions (SGX), TSX-NI, MPX, Trusted Execution, Secure Key, SSE4.1/4.2 and so on.

Intel Core i7 “Skylake-U” CPU Comparison
  Core i7-6660U Core i7-6650U Core i7-6600U Core i7-6500U Core i7-6567U
Cores/Threads 2/4
Base Frequency 2.4 GHz 2.2 GHz 2.6 GHz 2.5 GHz 3.3 GHz
Turbo Frequency unknown 3.4 GHz 3.4 GHz 3.1 GHz 3.6 GHz
L2 Cache 256 KB x 2 (512 KB)
L3 Cache 4 MB
Memory Dual-channel DRAM controller with
DDR4-2133, LPDDR3-1866, DDR3L-1600 support
iGPU Iris Graphics 540 Iris Graphics 540 HD Graphics 520 HD Graphics 520 Iris Graphics 550
iGPU Config 48 EUs 24 EUs 48 EUs
eDRAM 64 MB 64 MB
TDP 15 W 28 W
Configurable TDP-down unknown 9.5 W 7.5 W 23 W
Launch Q1 2016 Q3 2015
Price $415 $415 $393 $393 $415

The quiet addition of the Core i7-6660U into the price list indicates that Intel is starting to gradually refresh its Skylake lineup of products. It is unclear whether the refresh is conditioned by the upcoming spring refresh cycle of PC makers or higher yields of chips produced using the 14 nm process technology. Nonetheless, the new CPU will help PC makers to differentiate their new offerings and speed up performance in certain applications.

Source: Intel Price List via CPU-World.

Intel Quietly Speeds Up Skylake-U: i7-6660U now in Price List

Intel Quietly Speeds Up Skylake-U: i7-6660U now in Price List

Intel has quietly added a new Skylake-U processor into its price list. The new Intel Core i7-6660U system-on-chip is designed for low-power notebook systems and provides higher performance than its direct predecessor, the Core i7-6650U, and sits on the top of Intel’s 15W mobile CPU stack.

The new Intel Core i7-6660U belongs to the Skylake-U family of processors that feature CPU and PCH on the same piece of substrate and are used to build mobile PCs with low power consumption. The new chip is currently only listed in Intel’s price list, which reveals its general specs (two cores with hyperthreading, 4 MB L3 cache and 2.40 GHz clock-rate, no word on turbo) as well as its price of $415 in 1000-unit quantities. The CPU costs the same amount of money as the Core i7-6650U and the Core i7-6560U.

If the Core i7-6660U chip shares general design with its predecessor, then it features two cores with Hyper-Threading technology clocked at 2.40 GHz (up 200 MHz from the i7-6650U), 4 MB L3 cache, a dual-channel memory controller (support for DDR4-2133, LPDDR3-1866 and DDR3L-1600 memory), Intel Iris Graphics 540 (48 execution units with 64 MB eDRAM, up to 1.05 GHz clock rate, up to 806.4 GFLOPS compute performance) as well as a 15 W TDP. The new processor should also support all the technologies that other Skylake-generation mobile Core i7 chips support, including AES-NI, AVX 2, vPro, virtualization (VT-x, VT-d), software guard extensions (SGX), TSX-NI, MPX, Trusted Execution, Secure Key, SSE4.1/4.2 and so on.

Intel Core i7 “Skylake-U” CPU Comparison
  Core i7-6660U Core i7-6650U Core i7-6600U Core i7-6500U Core i7-6567U
Cores/Threads 2/4
Base Frequency 2.4 GHz 2.2 GHz 2.6 GHz 2.5 GHz 3.3 GHz
Turbo Frequency unknown 3.4 GHz 3.4 GHz 3.1 GHz 3.6 GHz
L2 Cache 256 KB x 2 (512 KB)
L3 Cache 4 MB
Memory Dual-channel DRAM controller with
DDR4-2133, LPDDR3-1866, DDR3L-1600 support
iGPU Iris Graphics 540 Iris Graphics 540 HD Graphics 520 HD Graphics 520 Iris Graphics 550
iGPU Config 48 EUs 24 EUs 48 EUs
eDRAM 64 MB 64 MB
TDP 15 W 28 W
Configurable TDP-down unknown 9.5 W 7.5 W 23 W
Launch Q1 2016 Q3 2015
Price $415 $415 $393 $393 $415

The quiet addition of the Core i7-6660U into the price list indicates that Intel is starting to gradually refresh its Skylake lineup of products. It is unclear whether the refresh is conditioned by the upcoming spring refresh cycle of PC makers or higher yields of chips produced using the 14 nm process technology. Nonetheless, the new CPU will help PC makers to differentiate their new offerings and speed up performance in certain applications.

Source: Intel Price List via CPU-World.

Intel and Tsinghua University to Co-Develop Semi-Custom Solutions for Servers

Intel and Tsinghua University to Co-Develop Semi-Custom Solutions for Servers

At present, investors state that Intel controls 98% of the server processor market with its Xeon CPUs, but the server market is changing. Intel’s acquisition of Altera is telling – many companies these days require chips with specific features and functionality, and as a result Intel has been making strides to add custom features to its processors. In an extension of this, this month Intel agreed to jointly work with Tsinghua University and Montage Technology to develop custom server platforms for servers used in China.

Under the terms of the agreement, Tsinghua University will develop a reconfigurable computing processor (RCP) module, as well as system software, that will work with a standard Intel Xeon CPU to add features that address requirements for specific applications in various market segments in Asia. The RCP will be made by outsourcing to a maker of semiconductors and it is likely that the government-controlled university may prefer to make the chip in the country or through a subsidiary.

The computing solution proposed consists of an Intel Xeon and a custom RCP, but will not be a multi-chip-module package designs like Intel’s Xeon processors with integrated Altera FPGAs. Instead we are told it will involve a different kind of packaging. Unfortunately, at present it is unclear whether Intel’s Xeon and Tsinghua’s RCP will communicate using known standards (such as the PCI Express interface, QPI, or other), or a custom protocol. 

Intel, TU and Montage did not disclose a lot of technical details about their joint semi-custom solution for Chinese datacenters, but re-configurability of processors implies that the final product could address a broad range of market segments. We postulated that the RCP is just another name for an FPGA, although our sources were unable to confirm this.

Intel will ensure that its chips work with RCPs, and will supply CPU dies to Montage Technology which will market the whole solution to interested parties. Montage plans to sell the final product, which will consist of a standard Intel Xeon CPU, a reconfigurable computing processor developed by Tsinghua, as well as software, in 2017. There is no information about specifications of the Xeon processor lines that will be used, nor the capabilities of the RCP, which still leaves the question of what range of CPUs are being discussed, if it is sub-25W or 90W+.

The collaboration between Intel, Tsinghua University and Montage is aimed to better address demands of Chinese state-owned and other datacenters. Since China is one of the world’s largest markets for servers, the importance of jointly working with local companies is something that is becoming very important not only for Intel, but for all developers of server CPUs, especially as news emerged last year about how Intel and others can or cannot sell to various entities. Intel has arrangements similar to this already in place, such as the Rockchip engagement for some smartphone-based SoCs to be made and sold by Rockchip in Asia, as well as arrangements with Spreadtrum (which is owned by Tsinghua Unigroup, to which Tsinghua University has sole investment).

Intel and Tsinghua University to Co-Develop Semi-Custom Solutions for Servers

Intel and Tsinghua University to Co-Develop Semi-Custom Solutions for Servers

At present, investors state that Intel controls 98% of the server processor market with its Xeon CPUs, but the server market is changing. Intel’s acquisition of Altera is telling – many companies these days require chips with specific features and functionality, and as a result Intel has been making strides to add custom features to its processors. In an extension of this, this month Intel agreed to jointly work with Tsinghua University and Montage Technology to develop custom server platforms for servers used in China.

Under the terms of the agreement, Tsinghua University will develop a reconfigurable computing processor (RCP) module, as well as system software, that will work with a standard Intel Xeon CPU to add features that address requirements for specific applications in various market segments in Asia. The RCP will be made by outsourcing to a maker of semiconductors and it is likely that the government-controlled university may prefer to make the chip in the country or through a subsidiary.

The computing solution proposed consists of an Intel Xeon and a custom RCP, but will not be a multi-chip-module package designs like Intel’s Xeon processors with integrated Altera FPGAs. Instead we are told it will involve a different kind of packaging. Unfortunately, at present it is unclear whether Intel’s Xeon and Tsinghua’s RCP will communicate using known standards (such as the PCI Express interface, QPI, or other), or a custom protocol. 

Intel, TU and Montage did not disclose a lot of technical details about their joint semi-custom solution for Chinese datacenters, but re-configurability of processors implies that the final product could address a broad range of market segments. We postulated that the RCP is just another name for an FPGA, although our sources were unable to confirm this.

Intel will ensure that its chips work with RCPs, and will supply CPU dies to Montage Technology which will market the whole solution to interested parties. Montage plans to sell the final product, which will consist of a standard Intel Xeon CPU, a reconfigurable computing processor developed by Tsinghua, as well as software, in 2017. There is no information about specifications of the Xeon processor lines that will be used, nor the capabilities of the RCP, which still leaves the question of what range of CPUs are being discussed, if it is sub-25W or 90W+.

The collaboration between Intel, Tsinghua University and Montage is aimed to better address demands of Chinese state-owned and other datacenters. Since China is one of the world’s largest markets for servers, the importance of jointly working with local companies is something that is becoming very important not only for Intel, but for all developers of server CPUs, especially as news emerged last year about how Intel and others can or cannot sell to various entities. Intel has arrangements similar to this already in place, such as the Rockchip engagement for some smartphone-based SoCs to be made and sold by Rockchip in Asia, as well as arrangements with Spreadtrum (which is owned by Tsinghua Unigroup, to which Tsinghua University has sole investment).